EP0323330A1 - Mould nozzle for the injection of plastic material - Google Patents

Abstract

Mould nozzle which consists of a cylindrical body forming a sleeve, associated with heating means and integrated into a receiving housing provided in the thickness of a mould, the nozzle entering the mould cavity via a downstream orifice and being able to receive, via its upstream orifice opposite the previous orifice, the flux of material injected from the press nozzle. The mould nozzle consists of a first fixed cylindrical sleeve (3) immobilized on the wall of the mould and comprising the said upstream orifice for the inlet of the material. The nozzle comprises a second movable sleeve (4), co-linear with the first, and mounted so as to slide telescopically inside the first sleeve, the end (5) of this second sleeve, opposite the end engaged in the first sleeve, bearing against the wall (9) of the receiving housing (8) provided in the thickness of the mould (2), the pressure of the injected material (4) thus tending to press the end of this sliding sleeve against the wall (9) of the housing while providing the sealing of the assembly. <IMAGE>

Description

The present invention relates to a nozzle passing through the walls of a mold intended to receive an injection of synthetic material in the plastic state.

The invention relates more specifically to a nozzle intended to be placed on a mold, passing through the thickness of the mold, an upstream end of the nozzle being connected to the injection machine, such as an injection press and being able to receive the flow of plastic material in the pasty state, the nozzle crossed by a longitudinal channel, emerging inside the mold by a downstream inlet orifice thus allowing the material injected from the press, to penetrate the inside the empty space defined by the mold and which, once filled with the cooled material, constitutes the molded object.

Such nozzles are generally provided with a collar which projects beyond the external wall of the mold, a collar by which the nozzle is fixed to the mold.

And the collar surrounds the upstream orifice through which the mold nozzle is brought into direct contact with the injection nozzle located on the press.

The nozzle is generally in the form of a generally cylindrical body passing through a housing arranged in the thickness of the walls of the mold to come out through the downstream end inside the mold, at the level of the cavity or the joint plane.

The nozzle is associated with heating means which make it possible to maintain the temperature of the injected material within the necessary limits until this material has penetrated inside the mold, avoiding cooling causing a start of solidification of the matter with obvious disadvantages both in terms of rheological functioning of the assembly only at the level of the distribution of the molded material within the mold.

The mold nozzles placed in the thickness of a mold must therefore, in the context of currently known techniques, be provided with dimensions allowing them, on the one hand, to come to bear by their external flange on the external wall of the mold. , while coming through their entry hole in the mold, in contact with the bottom of the receiver housing, bottom having an outlet in the interior of the mold.

These nozzles must therefore be adjusted extremely precisely so that their length, when the flange is in contact with the external surface of the mold, allows the opposite end to come into sealing contact with the bottom of the receiving housing .

We see that these characteristics are difficult to achieve, especially since it is necessary to take into account the expansion which necessarily affects the duct and the wall of the nozzle, when the latter is crossed by the flow of plastic material at a temperature in the range of 150 to 350 ° C.

The present invention relates to an improved nozzle which has considerable advantages over the prior system.

A first object of the invention is to produce a nozzle making it possible to adapt to variable dimensions of receptor housing, that is to say to variable thicknesses of mold.

Another object of the invention is to provide a nozzle which makes it possible to ensure effective and complete heating of the material until it penetrates inside the mold, avoiding any cooling zone.

This characteristic is particularly valuable in the increasingly frequent case where a molding material consisting of a resin mixture is used.

It may be advantageous to mold a particular product with not a homogeneous resin but a mixture of several resins each providing its specific characteristics.

However, it must be taken into account that each resin has a specific range of use which is defined by the temperature range between the softening temperature of the resin and the decomposition temperature; this range can sometimes be relatively narrow and last a few tens of degrees.

In the case of two resins in mixture, it is necessary to use this mixture in the niche, possibly very narrow, of temperature in which the two components are each within their useful temperature ranges (between softening and decomposition) .

Under these conditions, it is advantageous to have a nozzle which allows the temperature of the injected material to be adjusted and adjusted as far as the zone of entry into the impression.

Another object of the invention is to make it possible to obtain an automatic, constant and perfect seal between the downstream orifice of the nozzle, substantially at the outlet of the receiving housing towards the interior of the mold, and the wall of this housing placed in correspondence.

The invention also makes it possible to obtain an adaptation of the nozzle to conditions specific to each use, for example to passage diameters, allowing material flow rates according to different values.

For this purpose according to the invention there is provided a mold nozzle for plastic injection, consisting of a cylindrical body forming a sleeve, associated with heating means and integrated in a receiving housing provided in the thickness of a mold. , the nozzle opening through a downstream orifice inside the mold and being capable of receiving, through its upstream orifice, opposite to the previous one, the flow of material injected from the press nozzle, and the mold nozzle is characterized in that it consists of a first fixed cylindrical sleeve, immobilized on the wall of the mold and comprising said upstream orifice for the entry of the material, this orifice being capable of receiving in support the injection end of the press nozzle, and the nozzle comprises a second movable sleeve, collinear with the first, and mounted telescopically sliding inside the first sleeve, the end of this second sleeve, opposite the end engaged in the first sleeve, coming into abutment against the housing wall receiver provided in the thickness of the mold and constituting the outlet for the material molded into the cavity, the pressure of the injected material being exerted on the upstream section of the second sliding sleeve thus tending to press the opposite end of this sleeve sliding against the wall of the housing ensuring the tightness of the assembly.

According to another characteristic, the frustoconical end or second sleeve, opposite the end engaged in the first sleeve, has an angle of value less than the angle constituted by the frustoconical end of the receiving housing, on which said end of the sleeve comes to rest, the end cone of the sliding sleeve thus coming in circular contact with the frustoconical interior wall of the housing ensuring sealing and automatic self-centering from one wall to the other.

According to another characteristic, the fixed sleeve comprises, in a manner known per se, in its part projecting beyond the wall of the mold, a collar of diameter greater than the diameter of the receiving housing, said collar being fixed on the external wall of the mold.

According to another characteristic, the downstream opening of the nozzle, disposed at the downstream end of the sliding sleeve, comprises a transverse veil situated along a diameter of the internal channel passing through said sleeve, and this veil is extended to the outlet of the receptacle for receiving the nozzle in the interior space of the mold, said transverse web allowing the transmission of calories from the wall of said sliding sleeve to the threads of material being injected and penetrating inside the cavity.

According to a characteristic of the invention, the fixed sleeve internally comprises a cylindrical bore forming a chamber in which slides one end of the sliding sleeve, this chamber comprising a section of diameter greater than the diameter of the circumference defining the contact zone of the downstream tip of the sleeve. sliding on the frustoconical wall defining the bottom of the receptacle housing of the nozzle.

Other characteristics and advantages of the invention will emerge from the description which follows and which is given in relation to an embodiment presented by way of nonlimiting example and with reference to the appended figure.

It can be seen from the figure that on the mold 2, is mounted, by means of the collar 1, the fixed part 3 of the nozzle constituting the fixed sleeve.

In the chamber 6 constituting the internal bore of this sliding sleeve, is mounted movable and slidingly the mobile sleeve 4 sliding inside the chamber 6 and whose downstream end 5 is of generally frustoconical shape.

The entire nozzle is disposed inside the housing 8, the lower part 9 of which forms a frustoconical wall opening out at its center in the interior space of the mold 2.

Was provided at the frustoconical tip 5, a transverse web 7 disposed in the channel 10 along a diameter of said cylindrical channel; this veil extends down to the level of the outlet of the frustoconical bottom 9 of the housing 8 inside the space of the imprint.

The outer wall of the sliding sleeve 4 is provided, in a manner not shown, with a resistance which allows the heating of the nozzle and the maintenance of the material flow at a suitable temperature; the veil 7 thus transmits the calories from the walls of the sliding sleeve 4, as far as the threads of material in the course of flow and which penetrates into the mold.

We see that the cross section 6 'of the sliding sleeve, disposed inside the chamber 6, has a section on which the pressure of the material from the press is exerted; and this section is greater than the flow section of the material within the channel 10.

The cross section 6 ′ is in female tapered bevel, and the force exerted on this face thus comprises a centrifugal radial component which tends to press the top of the sliding sleeve on the receiving bore formed by the fixed sleeve.

In addition, the positive differential pressure causes the automatic placing of the tip 5 on the frustoconical receiving wall 9, thereby ensuring automatic sealing of the two zones in contact.

And this sealing is all the better ensured as the contact of the frustoconical tip 5, on the frustoconical face, of greater angle, 9 allows contact according to a circular zone with automatic self-centering.

Under these conditions, a perfect seal is obtained at the mold nozzle, obtained automatically without calculation and adapting to various values of thickness of the mold, the length of the nozzle automatically adapting to the length of the housing in which it is inserted.

We see that under these conditions a nozzle according to the invention can adapt to a range of receptacles of variable length.

It is therefore no longer necessary to provide a nozzle rigorously adjusted to the dimensions of the receiving housing; the adjustment can be very approximate and have very wide tolerances since automatically the pressure of the injected material will make up for the play and allow the sliding sleeve to be pressed into the bottom of the housing, thus ensuring the passage of the material.

Similarly there is no longer in the context of the implementation of the invention to be concerned with the problem of expansion during the arrival of the material and its passage through the nozzle, the possible expansion being automatically caught by a movement of the sliding sleeve inside the fixed sleeve 3.

Claims (5)

1 - Mold nozzle for plastic injection, consisting of a cylindrical body forming a sleeve, associated with heating means and integrated in a receiving housing provided in the thickness of a mold, the nozzle emerging through a downstream orifice in the imprint and being able to receive through its upstream orifice, opposite to the previous one, the flow of material injected from the press nozzle, and the mold nozzle is characterized in that it consists of a first fixed cylindrical sleeve ( 3), immobilized on the wall of the mold and comprising said upstream orifice for the entry of the material, this orifice being capable of receiving in support the injection end of the press nozzle, and the nozzle comprises a second movable sleeve (4), collinear with the first, and mounted telescopically sliding inside the first sleeve, the end (5) of this second sleeve, opposite the end engaged in the first sleeve, coming into abutment against the wall ( 9) of the receiver housing (8) provided in the shoulder mold issuer (2) and constituting the outlet for the molded material in the mold, the pressure of the injected material being exerted on the upstream section (6 ') of the second sliding sleeve (4) thus tending to press the opposite end (5) of this sleeve sliding against the wall (9) of the housing, ensuring the tightness of the assembly. 2 - Mold nozzle according to claim 1, characterized in that the frustoconical end (5) of the second sleeve (4), opposite the end engaged in the first sleeve, has an angle of value less than the angle formed by the frustoconical end (9) of the receiving housing (8), on which said end of the sleeve comes to bear, the inner cone of the sliding sleeve thus coming into circular contact with the wall frustoconical interior of the housing by ensuring sealing and automatic self-centering from one wall to the other. 3 - Nozzle according to one of claims 1 or 2, characterized in that the fixed sleeve (3) comprises, in a manner known per se, in its part projecting beyond the wall of the mold a flange (1) of diameter greater than the diameter of the receiver housing, said flange being fixed to the external wall of the mold. 4 - Nozzle according to one of claims 1,2 or 3, characterized in that the downstream opening of the nozzle, disposed at the downstream end of the sliding sleeve, comprises a transverse web (7) located along a diameter of the channel interior (10) passing through said sleeve, and this veil is extended to the outlet of the housing (8) receiving the nozzle in the interior space of the mold, said transverse veil allowing the transmission of calories from the wall of said sliding sleeve to the threads of material being injected and penetrating inside the mold. 5 - Nozzle according to one of claims 1,2,3 or 4, characterized in that the fixed sleeve (3) internally comprises a cylindrical bore (6) forming a chamber in which slides one end of the sliding sleeve (4), this chamber having a section with a diameter greater than the diameter of the circumference defining the contact zone of the downstream tip (5) of the sliding sleeve on the frustoconical wall (9) defining the bottom of the housing for receiving the nozzle.

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